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| United States Patent |
5,513,592
|
|
Cotton
|
May 7, 1996
|
Device for connecting a floating object to a moorage structure
Abstract
A mooring device for connecting a floating object to a moorage structure
includes an elongate resiliently yieldable member which has a
longitudinally-extending, normally arcuate shape when in an unstressed
state. The yieldable member is operatively connected between the floating
object at a first end and the moorage structure at a second end. The
yieldable member is yieldably bendable from the normally arcuate shape to
a more arcuate shape in response to movement of the floating object toward
the moorage structure so as to yieldably resist the movement. One
exemplary non-portable embodiment include a base which connects the second
end to the moorage structure. Another exemplary embodiment includes a
removable resilient fender which is adapted to connect the first end to
the floating object for portability. A third exemplary embodiment is
adapted selectively either for portable or non-portable use.
| Inventors:
|
Cotton; Oren L. (Eastsound, WA)
|
| Assignee:
|
Orcas Marine Products, Inc. (Eastsound, WA)
|
| Appl. No.:
|
490356 |
| Filed:
|
June 14, 1995 |
| Current U.S. Class: |
114/219; 405/219 |
| Intern'l Class: |
B63B 021/00 |
| Field of Search: |
114/219,230
405/219
D8/349,354
|
References Cited
U.S. Patent Documents
| 212143 | Feb., 1879 | Hulster.
| |
| 799645 | Sep., 1905 | Grimm.
| |
| 973906 | Oct., 1910 | Askegren | 114/251.
|
| 1094610 | Apr., 1914 | Steinhauer | 114/230.
|
| 1145749 | Jul., 1915 | Claud.
| |
| 2552424 | May., 1951 | Gorman.
| |
| 2569783 | Oct., 1951 | Smith.
| |
| 2662501 | Dec., 1953 | Bascome, Jr.
| |
| 2679818 | Jun., 1954 | Herbert et al. | 114/230.
|
| 2912953 | Nov., 1959 | Olsen | 114/230.
|
| 2930339 | Mar., 1960 | Trnka | 114/230.
|
| 2938492 | May., 1960 | Kulick.
| |
| 2996033 | Aug., 1961 | Yordi.
| |
| 3084517 | Apr., 1963 | Bell.
| |
| 3095848 | Jul., 1963 | Dick.
| |
| 3120831 | Feb., 1964 | Fulton.
| |
| 3157150 | Nov., 1964 | Faber.
| |
| 3187707 | Jun., 1965 | Carbone.
| |
| 3195498 | Jul., 1965 | Johns.
| |
| 3196824 | Jul., 1965 | Howard.
| |
| 3389675 | Jun., 1968 | Kieft et al. | 114/230.
|
| 4040377 | Aug., 1977 | Olsen | 114/230.
|
| 4250827 | Feb., 1981 | Booker et al. | 114/230.
|
| 4356783 | Nov., 1982 | Myklebust et al. | 114/230.
|
| 4686926 | Aug., 1987 | Vance | 114/230.
|
| 5013272 | May., 1991 | Watkins | 114/219.
|
| 5036787 | Aug., 1991 | Rogers | 114/230.
|
| 5154132 | Oct., 1992 | Brushaber | 114/230.
|
| 5361716 | Nov., 1994 | Cotton | 114/230.
|
| 5425324 | Jun., 1995 | Cotton | 114/230.
|
Primary Examiner: Sotelo; Jesus D.
Attorney, Agent or Firm: Chernoff, Vilhauer, McClung & Stenzel
Parent Case Text
This application is a continuation-in-part of application Ser. No.
08/315,953, filed Sep. 30, 1994, now U.S. Pat. No. 5,425,324.
Claims
What is claimed is:
1. A mooring device for connecting a floating object to a moorage
structure, said mooring device comprising:
(a) an elongate resiliently yieldable member having two ends and a
longitudinally-extending, normally arcuate shape when in an unstressed
state;
(b) said ends being adapted to be connected to said floating object and to
said moorage structure, respectively, so as to yieldably resist movement
of said floating object toward said moorage structure by bending from said
normally arcuate shape to a more arcuate shape in response to said
movement;
(c) at least one of said ends being pivotally attached to a pin so as to
pivot with respect to said pin about an axis substantially transverse to
said elongate resiliently yieldable member; and
(d) a socket mountable within at least one of said floating object and
moorage structure in communication with an exterior surface thereof, said
pin being slidably insertable into said socket through said exterior
surface and detachably lockable therein so as to fasten said pin within
said one of said floating object and moorage structure.
2. The mooring device of claim 1 wherein said pin is axially rotatable
relative to said socket.
3. The mooring device of claim 1 wherein said one of said ends is pivotally
attached to said pin so as to pivot with respect thereto about a pair of
mutually perpendicular axes both of which are substantially transverse to
said member.
4. The mooring device of claim 1 including a respective said pin and socket
associated with each of said ends of said member.
5. The mooring device of claim 1 wherein said resiliently yieldable member
has a generally elongate cross-section with a breadth substantially
greater than its thickness.
6. A mooring device for connecting a floating object to a moorage
structure, said mooring device comprising:
(a) an elongate resiliently yieldable member having two ends and a
longitudinally-extending, normally arcuate shape when in an unstressed
state;
(b) said ends being adapted to be connected to said floating object and to
said moorage structure, respectively, so as to yieldably resist movement
of said floating object toward said moorage structure by bending from said
normally arcuate shape to a more arcuate shape in response to said
movement;
(c) said ends being pivotally attachable to said floating object and to
said moorage structure, respectively, so that each of said ends pivots
with respect thereto about a respective substantially horizontal axis and
a substantially vertical axis, both of which are substantially transverse
to said member.
7. The mooring device of claim 6 wherein at least one of said ends is
pivotally attachable within an exterior surface of said floating object.
8. The mooring device of claim 6 wherein said resiliently yieldable member
has a generally elongate cross-section with a breath substantially greater
than its thickness.
9. A mooring device for connecting a floating object to a moorage
structure, said mooring device comprising:
(a) an elongate resiliently yieldable member having two ends and a
longitudinally-extending, normally arcuate shape when in an unstressed
state:
(b) said ends being adapted to be connected to said floating object and to
said moorage structure, respectively, so as to yieldably resist movement
of said floating object toward said moorage structure by bending from said
normally arcuate shape to a more arcuate shape in response to said
movement;
(c) said ends having respective spring lines fastened thereto and being
detachable from said floating object and said moorage structure,
respectively, in unison with said respective spring lines.
10. The mooring device of claim 9 wherein said resiliently yieldable member
has a generally elongate cross-section with a breadth substantially
greater than its thickness.
Description
BACKGROUND OF THE INVENTION
The present invention relates to a device for connecting a floating object
to a moorage structure and particularly to a fiberglass mooring device for
mooring a vessel to a dock, pier, or moorage float.
Floating objects such as boats, vessels, or platforms are traditionally
moored alongside moorage structures such as docks, piers, or floats by use
of mooring lines and resilient fenders. However, when a floating object is
moored to a moorage structure using traditional devices, during severe or
stormy conditions the floating object, the moorage structure, or both are
generally subject to damage. Fenders placed between the floating object
and the moorage structure as a buffer are easily dislodged or otherwise
are insufficient to prevent damage. Further, where currents, storm waves,
or wakes of passing vessels cause significant or prolonged relative
movement, traditional fenders may rub the surfaces of the floating object
and cause considerable damage to the paint or other surface finish.
Another problem with traditional devices for attaching floating objects to
moorage structures is the necessity to adjust conventional mooring lines
in response to tidal rise and fall of the water with respect to the
moorage structure. No such adjustment is needed when the moorage structure
is a float which is free to rise and fall on the tide. Even with floats,
however, it is sometimes difficult to limit movement of a floating object
to the extent desired without undesirably straining mooring lines when the
floating object moves relative to the moorage structure in response to
storm waves or wakes of passing vessels.
Mooring whips are one type of device used to connect a floating object to a
moorage structure. These whips consist of a highly flexible straight rod
or pole which is securely and permanently fastened to a moorage structure.
Whips are an improvement over other devices in that they allow for
adjustment in heights due to tides. However, because a mooring whip is
essentially straight when it is not connected to the floating object, it
must be highly flexible so that it can be bent manually to connect its
free end to the floating object. This high degree of flexibility, however,
often allows too much movement of the floating object which can then come
in contact with the moorage structure and thereby cause damage under
severe wave or wake conditions. Another problem with mooring whips is that
they are generally permanently installed on moorage structures and are not
portable to enable their use in connecting a floating object to alternate
moorage structures having no permanently installed mooring whips.
What is needed, then, is a mooring device which, although resiliently
yieldable, is much less flexible than a conventional mooring whip and is
of simple, inexpensive construction, capable of quiet operation and
adaptable to floating objects and/or moorage structures of differing
configurations. The mooring device should be usable either in combination
with or independent of conventional mooring lines to control movement of a
floating object with respect to a moorage structure with sufficient
resilient resistance to prevent contact between the moorage structure and
the floating object under severe conditions. Preferably, the mooring
device should also be portable and attachable to alternative moorage
structure.
SUMMARY OF THE INVENTION
A mooring device according to the present invention includes an elongate
resiliently yieldable member which has a longitudinally-extending,
normally arcuate shape when in an unstressed state. The yieldable member
is operatively connected between the floating object at a first end and
the moorage structure at a second end, and is yieldably bendable from the
normally arcuate shape to a more arcuate shape in response to movement of
the floating object toward the moorage structure so as to yieldably resist
the movement.
According to one aspect of the invention, the interconnection of the
mooring device with the floating object and/or the moorage structure is
easily attachable and detachable without requiring any connecting hardware
protruding significantly from the attachment surface of the floating
object and/or the moorage structure.
According to another aspect of the invention, such interconnection is
highly versatile to accommodate attachment surfaces of different
orientations and heights.
According to another aspect of the invention, such interconnection isolates
the attachment surface from torques imposed about both horizontal and
vertical axes.
According to another aspect of the invention, such interconnection also
automatically attaches and detaches spring lines.
According to another aspect of the invention, the mooring device may be
easily and removably transported on a floating object to be used in
connecting to alternative moorage structures.
The foregoing and other objectives, features, and advantages of the
invention will be more readily understood upon consideration of the
following detailed description of the invention, taken in conjunction with
the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a side view of an exemplary non-portable embodiment of the
present invention including a base having multiple attachment positions.
FIG. 2 is a side view of an exemplary non-portable embodiment of a base of
the present invention having a single attachment position.
FIG. 3 is a partial front view of the embodiment of FIG. 1.
FIG. 4 is a partial sectional side view taken along line 4--4 of FIG. 3.
FIG. 5 is a top view showing a pair of mooring devices in accordance with
the embodiment of FIG. 1 connecting a floating object to a moorage
structure.
FIG. 6 is a side view of the embodiment of FIG. 1 in an unstressed state.
FIG. 7 is a side view of the embodiment of FIG. 1 in a stressed state.
FIG. 8 is a front view of a portable exemplary embodiment of the present
invention including a fender for detachably mounting to a floating object.
FIG. 9 is a partial sectional view taken along line 9--9 of FIG. 8.
FIG. 10 is a top view of the exemplary embodiment of FIG. 8 shown attached
to a floating object using a fender, and connecting the floating object to
a moorage structure.
FIG. 11 is a side view of the embodiment of FIG. 8 in an unstressed state.
FIG. 12 is a side view of a further exemplary embodiment of the present
invention which is especially easy to attach and detach and which is
usable selectively either portably or non-portably.
FIG. 13 is a cross-sectional view of the detachable interconnecting
structure used in FIG. 12.
FIG. 14 is a partial side view of an alternative detachable interconnecting
structure which may be used in the embodiment of FIG. 12.
FIG. 15 is a plan view showing the embodiment of FIG. 12 in use.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
An exemplary non-portable embodiment of a mooring device, indicated
generally as 20, for connecting a floating object 16 (FIG. 5) to a moorage
structure 18 comprises, as shown in FIG. 1, an elongate resiliently
yieldable member 22 attached to a base 28 which is adapted for affixing to
a moorage structure 18. One end 24 of the yieldable member 22 is
preferably adapted to be removably connected to a floating object 16 and
the other end 26 of the yieldable member 22 is pivotally attached to the
base 28.
More specifically, FIG. 1 shows an exemplary embodiment of the present
invention 20 including an elongate resiliently yieldable member 22 which
has a longitudinally-extending, normally arcuate shape when in an
unstressed state, as shown also in FIG. 6. The yieldable member 22 is
capable of providing an unusually stiff yieldable resistance to movement
of the floating object 16 toward the moorage structure 18 by bending from
the normally arcuate shape in the unstressed state (FIG. 6) to a slightly
more arcuate shape in a stressed state as shown in FIG. 7. The yieldable
member 22 in this embodiment may be a fiberglass leaf spring which has an
approximate width of 3 inches, an approximate base-to-tip linear dimension
of 34 inches, and an approximate average unstressed radius of curvature of
24 inches. The thickness of the member 22 may vary from about 0.30 inch in
the areas adjacent its two ends to about 0.35 inch in its central area. It
should be noted that other materials such as metals or plastics may be
used to form the member 22, and that the dimensions given are meant to be
exemplary and could be modified for reasons including the use of different
materials and varying sizes of floating object 16.
Referring again to FIG. 1, the member 22 has an end 24 adapted to be
removably connected to the floating object 16. In the preferred
embodiment, the end 24 would have two bores 32 defined therein (as shown
in FIG. 3) through which a mooring line 34 or rope may be threaded. The
ends of the mooring line 34 may be individually knotted, as shown in FIG.
5, or tied together. The effective length of the mooring line 34 may be
adjusted by changing the positions of the knots. The loop formed by the
mooring line 34 may be attached to a cleat 36 commonly found on floating
objects 16 such as boats. Alternate embodiments of the end 24 may also be
used, including alternate attachment devices. For example, the end 24 may
include a metal hook or clasp which may attach to the cleat 36.
The end 26 of the yieldable member 22 opposite the end 24 is attached to a
base 28 which is preferably adapted for affixing to a moorage structure
18. The base 28 may be attached directly to the moorage structure 18 by
bolting the base 28 thereto. If desired, a backing plate such as an
additional piece of wood or metal 38, which is long enough to span several
planks of the moorage structure, can be used for added strength. Another
alternate method of attaching the base 28 to the moorage structure 18
would be to through bolt the base 28 to a bull rail 40 (FIG. 2) which is
attached to and commonly found on moorage structures 28.
In the embodiments shown in FIGS. 1 and 2, the bases 28 and 28a each have a
back such as 46 and two sides such as 48 which are attached along the
longitudinal edges of the back 46 as shown with respect to base 28 in
FIGS. 3 and 4. The base may be a single height base 28a, such as the
embodiment shown in FIG. 2, which includes only one attachment position
for the end 26 of the leaf spring 22 consisting of a set of bores (not
shown) on either side of the base 42 through which a bolt 62 passes. This
embodiment is preferably used when the expected difference in height
between the mounted end 26 of the member 22 and the cleat 36 on the
floating object 16 is small, i.e., no more than approximately 6 inches.
The base may alternatively be a multiple height base 28 as shown in FIG. 1
which includes multiple attachment positions at different heights for
selective attachment of the end 26 of the yieldable member 22 to the base
28 at different heights approximately equal to the height of the cleat 36
on the particular floating object 16. Each attachment position preferably
includes a set of bores 30 on either side of the base 28 through which a
bolt 62 may pass. This embodiment is preferably used when the difference
in height between the mounted base 28 and the cleat 36 on the floating
object 16 will vary, such as when different floating objects 16 are to be
accommodated.
FIGS. 3 and 4 show the pivotal attachment of the end 26 of the yieldable
member 22 to the base 28 of FIG. 1. The end 26 is pivotally attached to
the base 28 by a pivoted biasing device 50 that enables the yieldable
member 22 to be pivoted upwardly from the moorage structure 18 with the
aid of the biasing device 50 when the end 24 is free of the floating
object 16, and pivoted downwardly in opposition to the biasing device 50
to allow the end 24 to connect to the floating object 16 without requiring
any bending of the yieldable member 22 from its normally arcuate shape.
The pivoted biasing device 50 preferably includes an upwardly-biasing
spring 52 such as a return spring which is less resistant to bending than
the yieldable member 22 and which enables said member to be pivoted
downwardly without bending from its normally arcuate shape while imposing
an upward pressure on the end 24. The end 26 is preferably connected to a
metal tube or sleeve 54 preferably having a length greater than the width
of the yieldable member 22. The end 26 may be connected to the tube 54
using metal plates 56 on either side of the end 26 which are welded to the
tube 54 and bolted to the end 26 using bolts 58. An optional bushing 60
may be inserted through the tube 54 to prevent excess wear as the tube
pivots about the bolt 62. This configuration allows the spring 52 to
tighten as the yieldable member 22 is lowered, thus providing an upward
pressure on the end 24 of the yieldable member 22 (as shown in FIGS. 6 and
7). This upward pressure keeps the mooring line 34 from unfastening from
the cleat 36 and also keeps the end 24 of the member 22 from striking the
cleat on the floating object 16 as the floating object moves toward and
away from the moorage structure.
FIG. 5 shows a floating object 16 attached to a moorage structure 18 using
mooring devices 20 which include bases 28. Spring lines 68 may be included
to keep the floating object 16 from moving forward or aft to relieve undue
stress on the mooring devices 20. Additional bumpers or fenders 70 may
also be used for extra protection of the floating object 16.
FIG. 8 shows an alternate exemplary portable embodiment 20a of the mooring
device including a fender 80, for connecting a floating object 16 (FIG.
10) to a moorage structure 18 (FIG. 10). The alternate embodiment 20a
comprises, as shown in FIG. 8, an elongate resiliently yieldable member
22a, an end 24 adapted to be removably connected to the moorage structure
18, and an end 26 attached to a fender 80 which is adapted to be removably
attached to the floating object 16. Like the embodiment discussed above,
the elongate resiliently yieldable member 22a has a
longitudinally-extending, normally arcuate shape when in an unstressed
state (FIG. 11). The yieldable member 22a functions like the previously
described member 22 to provide yieldable resistance to movement of the
floating object 16 toward the moorage structure 18, and may be a
fiberglass leaf spring having the same dimensions as member 22.
Preferably, however, the member 22a is somewhat shorter and thinner than
the member 22, having an approximate linear base-to-tip dimension of 28
inches, an end thickness of about 0.24 inch, and a central thickness of
about 0.27 inch. The radius of curvature and width are approximately the
same as described previously.
The fender 80 may be made of any resilient, water-impermeable material such
as a flexible plastic, rubber, or closed-cell foam, and is preferably of
the type shown in U.S. Pat. No. 5,013,272 which is hereby incorporated by
reference. Alternatively, other structures such as a bracket which may be
removably secured to the floating object 16 could be used to attach the
yieldable member 22a to the floating object and prevent the end 26 from
coming in contact with and damaging the floating object 16.
Referring again to FIG. 8, the alternate portable embodiment 20a of the
mooring device has an end 24 with a mooring line 34 similar to that of the
previous embodiment 20 but, in this case, adapted to be removably
connected to the moorage structure 18 rather than the floating object 16.
The end 26 opposite the end 24 is attached to the fender 80 which is
adapted to be removably attached to the floating object 16 at different
heights so that the end 26 of the member 22a is at approximately the same
height as a cleat 36 on the moorage structure.
The resilient fender 80 has two longitudinal channels 82 through which a
mooring line 84 or rope may be threaded. The ends of the mooring line 84
may be tied together as shown in FIG. 8 or individually knotted. The
mooring line 84 is length-adjustable by adjustment of the knot or knots to
change the height of the fender 80. The center section of the mooring line
84 forms a loop which may be attached to a cleat 36 commonly found on
floating objects 16 such as boats (FIG. 10).
FIGS. 8 and 9 show the attachment of the end 26 of the yieldable member 22a
to the fender 80. The end 26 has a metal tube or sleeve 54a similar to
tube 54 of the previous embodiment. An optional bushing 60 may be inserted
through the tube 54a to prevent excess wear and chafing of a rope 86 which
is used to pivotally connect the end 26 to the fender 80. As best seen in
FIG. 9, the center portion of the rope 86 is threaded through the tube 54a
and the bushing 60, and then through a first set of channels 88 which
extend through the thickness of the fender 80. The rope 86 then wraps
around the back of the fender 80 and threads back through a second set of
channels 90. The ends of the mooring line 86 may be individually knotted
or may be tied together. Additional reinforcement 92 such as a plastic or
metal plate may be added to the fender 80 to prevent the fender 80 from
tearing or abrading.
An additional feature which may be included in the portable embodiment 20a
is that the yieldable member 22a may be detachable from the fender 80 for
easy storage on the floating object 16. This feature, as shown in FIG. 9,
comprises a slot 55 having the width of the rope 86 cut along the entire
length of the tube 54a. The slot is located approximately 90.degree. from
the end 26 of the yieldable member 22a on the concave side of the member
22a. For detachment from the rope 86, the member 22a may be rotated
approximately 180.degree. downward so that the slot 55 faces the fender
and is aligned with the rope 86. The tube 54a may then be slid off the
rope 86, and the fender 80 and member 22a can be stored separately.
FIG. 10 shows a floating object 16 attached to a moorage structure 18 using
the portable alternate embodiment 20a of the mooring device. Spring lines
68 may be included to keep the floating object 16 from moving forward or
aft to relieve undue stress from the mooring device 20a. Additional
bumpers or fenders 70 may also be used for extra protection of the
floating object 16.
It should be noted that the first exemplary embodiment could be adapted so
that the base 28 attaches directly to a floating object 16 and the end 24
of the yieldable member 22 could then attach to a cleat 36 on a moorage
structure 18. It should also be noted that, in the alternate portable
exemplary embodiment, the fender 80 could be adapted to be attached to a
cleat 36 on a moorage structure 18 and the end 24 of the yieldable member
22a could attached to a cleat 36 on a floating object 16.
FIG. 12 shows a further alternate exemplary embodiment 20b of the mooring
device comprising an elongate resiliently yieldable member 22b connecting
a floating object 16 to a moorage structure 18. The mooring device 20b is
especially easy to attach and detach, may be used either portably or
nonportably, and does not require the presence of cleats either on the
floating object 16 or on the moorage structure 18. (However, if desired, a
loop of mooring line or other suitable attachment device may optionally be
provided on either end of the member 22b for attachment to a cleat.)
Like the previous embodiments, the elongate resiliently yieldable member
22b has a longitudinally-extending normally arcuate shape when in an
unstressed state, and functions to provide yieldable resistance to
movement of the floating object 16 toward the moorage structure 18. The
member 22b is preferably a fiberglass leaf spring having a higher
volumetric percentage of glass fibers (about 65%) than the previous
embodiments (about 50%), and thus is stiffer. Therefore its width can be
about 1.75 inches and its thickness about 0.25 inches, with a linear
length of about 32 inches and a radius of curvature similar to that of the
previous embodiments. Each end of member 22b has a respective clevis 100
rigidly affixed thereto, each clevis 100 having a respective horizontal
clevis pin 102 to which is pivotally attached a respective connection pin
104. Each connection pin 104 is slidably insertable detachably into a
respective socket 106 mounted within the respective floating object 16 or
moorage structure 18, in a manner to be described hereafter. Each pin 104
is also pivotable about its vertical axis with respect to its socket 106
so that each end of the member 22b pivots with respect to the floating
object 16 or moorage structure 18 about a respective pair of mutually
perpendicular axes, one generally horizontal and the other generally
vertical, and both generally transverse to the member 22b. The horizontal
axis of each clevis pin 102 provides pivoting to isolate the socket 106
from torques imposed by toward-and-away motions and vertical motions of
the floating object 16 relative to the moorage structure 18, while the
vertical axis of rotation of each pin 104 isolates the socket 106 from
torques due to horizontal motions of the floating object 16 parallel to
the moorage structure 18.
Each clevis 100 contains a respective aperture 108 formed therein for
fastening a respective spring line 110 thereto, as shown in FIG. 15, so
that the spring lines 110 are automatically attached and detached from the
floating object 16 or moorage structure 18 in unison with the member 22b.
With reference to FIG. 13, each socket 106 comprises an externally threaded
socket member 112 insertable through an aperture 114 which the user cuts
through the exterior surface of the floating object 16 and/or moorage
structure 18. The socket 106 has an exterior flange 116, from the
underside of which a nut 118 may be tightened to clamp the socket 106 in
place within the aperture 114. Depending upon the application and the need
for water-tightness, appropriate caulking or a resilient gasket may be
placed on the underside of the flange 116 to form a liquid-impervious
seal.
With reference to FIG. 12, for mounting the socket 106 within a moorage
structure 18, a larger aperture 114a may be drilled with a sufficient
diameter to accept the insertion of the nut 118. The socket 106 is
fastened by means of the nut 118 to a steel plate which is then bolted to
the moorage structure 18, with the nut 118 recessed within the aperture
114a. This eliminates the need to apply the nut 118 from within the
moorage structure, which could otherwise be difficult or impossible.
The pin 104 is slidably and rotatably insertable into the socket 106 by
inserting the pin 104 while pressing downwardly on a lever 120, thereby
depressing a plunger 121 against a spring 122 and enabling locking
elements 124 to move inwardly into an annular groove 126 on the plunger
121 and thereby slide through an annular locking member 128 fixed to the
inside of the socket member 112. Release of the lever 120 forces the
locking elements 124 outwardly and prevents their withdrawal through the
locking member 128 until the user once more depresses the lever 120 and
withdraws the pin 104 from the socket 106.
If it is necessary to mount a socket 106 within a substantially vertical
surface on the floating object 16 or moorage structure 18 in order to
achieve a substantially equal height relationship between the two sockets
106, the respective socket 106 may be mounted within such a vertical
surface in the same manner as previously described with respect to FIGS.
12 and 13. In such case it is desirable to employ an alternate connection
pin 104a (FIG. 14) which, although otherwise identical to connection pin
104 described previously, does not connect directly to clevis pin 102 but
rather connects thereto through a post 130 which mounts perpendicular to
the pin 104a and rotates axially with respect thereto while retained by a
snap ring 131. Such axial rotation of the post 130 provides the
vertical-axis pivoting described previously which isolates the socket 106
from torques due to horizontal motions of the floating object 16 parallel
to the moorage structure 18. The use of vertical attachment surfaces at
both ends of a member 22b should be avoided because the three axes of
rotation allowed by pins 104a, if present at both ends, would allow member
22b to rotate longitudinally.
In use, a pair of the members 22b are attached to the top horizontal
surface or the front vertical surface of a moorage structure 18 using
sockets 106 and pins 104 or 104a, and interconnected by spring lines 110
attached to apertures 108 in the respective clevises 100 as shown in FIG.
15. Similar sockets 106 are attached to horizontal or vertical attachment
surfaces of a floating object 16 at approximately the same level and
horizontal spacing as the sockets 106 on the moorage structure. The
members 22b are detachably connected to the floating object 16 by means of
pins 104 or 104a.
Detachment of the floating object from the moorage structure can be
accomplished quickly simply by detaching the pins 104 or 104a from the
sockets 106 on the floating object by depression of the levers 120. If it
is desired to transport the members 22b portably with the floating object
16, they are detached at both ends and stowed, with their spring lines
attached, in the floating object for later attachment to another moorage
structure or another floating object having sockets 106 of matching
spacing and height.
Alternatively, only a single member 22b could be attachable to a floating
object by a socket 106 installed midway between the bow and stern. In such
case the member 22b could be carried portably for attachment to an
ordinary cleat on a moorage structure using a loop of mooring line or
other cleat-attaching device in the same manner as shown in FIG. 10.
It should be noted that the various embodiments may be used independently
and do not necessarily need mooring lines and fenders. Also, since the
mooring device is intended to be used near water in varying climates, the
materials used to construct the mooring device are preferably weather
resistant and otherwise sturdy.
The terms and expressions which have been employed in the foregoing
specification are used therein as terms of description and not of
limitation, and there is no intention, in the use of such terms and
expressions, of excluding equivalents of the features shown and described
or portions thereof, it being recognized that the scope of the invention
is defined and limited only by the claims which follow.
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